from typing import Any, Dict

from sympy.testing.pytest import raises
from sympy import (symbols, sympify, Function, Integer, Matrix, Abs,
    Rational, Float, S, WildFunction, ImmutableDenseMatrix, sin, true, false, ones,
    sqrt, root, AlgebraicNumber, Symbol, Dummy, Wild, MatrixSymbol, Q)
from sympy.combinatorics import Cycle, Permutation
from sympy.core.symbol import Str
from sympy.geometry import Point, Ellipse
from sympy.printing import srepr
from sympy.polys import ring, field, ZZ, QQ, lex, grlex, Poly
from sympy.polys.polyclasses import DMP
from sympy.polys.agca.extensions import FiniteExtension

x, y = symbols('x,y')

# eval(srepr(expr)) == expr has to succeed in the right environment. The right
# environment is the scope of "from sympy import *" for most cases.
ENV = {"Str": Str}  # type: Dict[str, Any]
exec("from sympy import *", ENV)


def sT(expr, string, import_stmt=None):
    """
    sT := sreprTest

    Tests that srepr delivers the expected string and that
    the condition eval(srepr(expr))==expr holds.
    """
    if import_stmt is None:
        ENV2 = ENV
    else:
        ENV2 = ENV.copy()
        exec(import_stmt, ENV2)

    assert srepr(expr) == string
    assert eval(string, ENV2) == expr


def test_printmethod():
    class R(Abs):
        def _sympyrepr(self, printer):
            return "foo(%s)" % printer._print(self.args[0])
    assert srepr(R(x)) == "foo(Symbol('x'))"


def test_Add():
    sT(x + y, "Add(Symbol('x'), Symbol('y'))")
    assert srepr(x**2 + 1, order='lex') == "Add(Pow(Symbol('x'), Integer(2)), Integer(1))"
    assert srepr(x**2 + 1, order='old') == "Add(Integer(1), Pow(Symbol('x'), Integer(2)))"
    assert srepr(sympify('x + 3 - 2', evaluate=False), order='none') == "Add(Symbol('x'), Integer(3), Mul(Integer(-1), Integer(2)))"


def test_more_than_255_args_issue_10259():
    from sympy import Add, Mul
    for op in (Add, Mul):
        expr = op(*symbols('x:256'))
        assert eval(srepr(expr)) == expr


def test_Function():
    sT(Function("f")(x), "Function('f')(Symbol('x'))")
    # test unapplied Function
    sT(Function('f'), "Function('f')")

    sT(sin(x), "sin(Symbol('x'))")
    sT(sin, "sin")


def test_Geometry():
    sT(Point(0, 0), "Point2D(Integer(0), Integer(0))")
    sT(Ellipse(Point(0, 0), 5, 1),
       "Ellipse(Point2D(Integer(0), Integer(0)), Integer(5), Integer(1))")
    # TODO more tests


def test_Singletons():
    sT(S.Catalan, 'Catalan')
    sT(S.ComplexInfinity, 'zoo')
    sT(S.EulerGamma, 'EulerGamma')
    sT(S.Exp1, 'E')
    sT(S.GoldenRatio, 'GoldenRatio')
    sT(S.TribonacciConstant, 'TribonacciConstant')
    sT(S.Half, 'Rational(1, 2)')
    sT(S.ImaginaryUnit, 'I')
    sT(S.Infinity, 'oo')
    sT(S.NaN, 'nan')
    sT(S.NegativeInfinity, '-oo')
    sT(S.NegativeOne, 'Integer(-1)')
    sT(S.One, 'Integer(1)')
    sT(S.Pi, 'pi')
    sT(S.Zero, 'Integer(0)')


def test_Integer():
    sT(Integer(4), "Integer(4)")


def test_list():
    sT([x, Integer(4)], "[Symbol('x'), Integer(4)]")


def test_Matrix():
    for cls, name in [(Matrix, "MutableDenseMatrix"), (ImmutableDenseMatrix, "ImmutableDenseMatrix")]:
        sT(cls([[x**+1, 1], [y, x + y]]),
           "%s([[Symbol('x'), Integer(1)], [Symbol('y'), Add(Symbol('x'), Symbol('y'))]])" % name)

        sT(cls(), "%s([])" % name)

        sT(cls([[x**+1, 1], [y, x + y]]), "%s([[Symbol('x'), Integer(1)], [Symbol('y'), Add(Symbol('x'), Symbol('y'))]])" % name)


def test_empty_Matrix():
    sT(ones(0, 3), "MutableDenseMatrix(0, 3, [])")
    sT(ones(4, 0), "MutableDenseMatrix(4, 0, [])")
    sT(ones(0, 0), "MutableDenseMatrix([])")


def test_Rational():
    sT(Rational(1, 3), "Rational(1, 3)")
    sT(Rational(-1, 3), "Rational(-1, 3)")


def test_Float():
    sT(Float('1.23', dps=3), "Float('1.22998', precision=13)")
    sT(Float('1.23456789', dps=9), "Float('1.23456788994', precision=33)")
    sT(Float('1.234567890123456789', dps=19),
       "Float('1.234567890123456789013', precision=66)")
    sT(Float('0.60038617995049726', dps=15),
       "Float('0.60038617995049726', precision=53)")

    sT(Float('1.23', precision=13), "Float('1.22998', precision=13)")
    sT(Float('1.23456789', precision=33),
       "Float('1.23456788994', precision=33)")
    sT(Float('1.234567890123456789', precision=66),
       "Float('1.234567890123456789013', precision=66)")
    sT(Float('0.60038617995049726', precision=53),
       "Float('0.60038617995049726', precision=53)")

    sT(Float('0.60038617995049726', 15),
       "Float('0.60038617995049726', precision=53)")


def test_Symbol():
    sT(x, "Symbol('x')")
    sT(y, "Symbol('y')")
    sT(Symbol('x', negative=True), "Symbol('x', negative=True)")


def test_Symbol_two_assumptions():
    x = Symbol('x', negative=0, integer=1)
    # order could vary
    s1 = "Symbol('x', integer=True, negative=False)"
    s2 = "Symbol('x', negative=False, integer=True)"
    assert srepr(x) in (s1, s2)
    assert eval(srepr(x), ENV) == x


def test_Symbol_no_special_commutative_treatment():
    sT(Symbol('x'), "Symbol('x')")
    sT(Symbol('x', commutative=False), "Symbol('x', commutative=False)")
    sT(Symbol('x', commutative=0), "Symbol('x', commutative=False)")
    sT(Symbol('x', commutative=True), "Symbol('x', commutative=True)")
    sT(Symbol('x', commutative=1), "Symbol('x', commutative=True)")


def test_Wild():
    sT(Wild('x', even=True), "Wild('x', even=True)")


def test_Dummy():
    d = Dummy('d')
    sT(d, "Dummy('d', dummy_index=%s)" % str(d.dummy_index))


def test_Dummy_assumption():
    d = Dummy('d', nonzero=True)
    assert d == eval(srepr(d))
    s1 = "Dummy('d', dummy_index=%s, nonzero=True)" % str(d.dummy_index)
    s2 = "Dummy('d', nonzero=True, dummy_index=%s)" % str(d.dummy_index)
    assert srepr(d) in (s1, s2)


def test_Dummy_from_Symbol():
    # should not get the full dictionary of assumptions
    n = Symbol('n', integer=True)
    d = n.as_dummy()
    assert srepr(d
        ) == "Dummy('n', dummy_index=%s)" % str(d.dummy_index)


def test_tuple():
    sT((x,), "(Symbol('x'),)")
    sT((x, y), "(Symbol('x'), Symbol('y'))")


def test_WildFunction():
    sT(WildFunction('w'), "WildFunction('w')")


def test_settins():
    raises(TypeError, lambda: srepr(x, method="garbage"))


def test_Mul():
    sT(3*x**3*y, "Mul(Integer(3), Pow(Symbol('x'), Integer(3)), Symbol('y'))")
    assert srepr(3*x**3*y, order='old') == "Mul(Integer(3), Symbol('y'), Pow(Symbol('x'), Integer(3)))"
    assert srepr(sympify('(x+4)*2*x*7', evaluate=False), order='none') == "Mul(Add(Symbol('x'), Integer(4)), Integer(2), Symbol('x'), Integer(7))"


def test_AlgebraicNumber():
    a = AlgebraicNumber(sqrt(2))
    sT(a, "AlgebraicNumber(Pow(Integer(2), Rational(1, 2)), [Integer(1), Integer(0)])")
    a = AlgebraicNumber(root(-2, 3))
    sT(a, "AlgebraicNumber(Pow(Integer(-2), Rational(1, 3)), [Integer(1), Integer(0)])")


def test_PolyRing():
    assert srepr(ring("x", ZZ, lex)[0]) == "PolyRing((Symbol('x'),), ZZ, lex)"
    assert srepr(ring("x,y", QQ, grlex)[0]) == "PolyRing((Symbol('x'), Symbol('y')), QQ, grlex)"
    assert srepr(ring("x,y,z", ZZ["t"], lex)[0]) == "PolyRing((Symbol('x'), Symbol('y'), Symbol('z')), ZZ[t], lex)"


def test_FracField():
    assert srepr(field("x", ZZ, lex)[0]) == "FracField((Symbol('x'),), ZZ, lex)"
    assert srepr(field("x,y", QQ, grlex)[0]) == "FracField((Symbol('x'), Symbol('y')), QQ, grlex)"
    assert srepr(field("x,y,z", ZZ["t"], lex)[0]) == "FracField((Symbol('x'), Symbol('y'), Symbol('z')), ZZ[t], lex)"


def test_PolyElement():
    R, x, y = ring("x,y", ZZ)
    assert srepr(3*x**2*y + 1) == "PolyElement(PolyRing((Symbol('x'), Symbol('y')), ZZ, lex), [((2, 1), 3), ((0, 0), 1)])"


def test_FracElement():
    F, x, y = field("x,y", ZZ)
    assert srepr((3*x**2*y + 1)/(x - y**2)) == "FracElement(FracField((Symbol('x'), Symbol('y')), ZZ, lex), [((2, 1), 3), ((0, 0), 1)], [((1, 0), 1), ((0, 2), -1)])"


def test_FractionField():
    assert srepr(QQ.frac_field(x)) == \
        "FractionField(FracField((Symbol('x'),), QQ, lex))"
    assert srepr(QQ.frac_field(x, y, order=grlex)) == \
        "FractionField(FracField((Symbol('x'), Symbol('y')), QQ, grlex))"


def test_PolynomialRingBase():
    assert srepr(ZZ.old_poly_ring(x)) == \
        "GlobalPolynomialRing(ZZ, Symbol('x'))"
    assert srepr(ZZ[x].old_poly_ring(y)) == \
        "GlobalPolynomialRing(ZZ[x], Symbol('y'))"
    assert srepr(QQ.frac_field(x).old_poly_ring(y)) == \
        "GlobalPolynomialRing(FractionField(FracField((Symbol('x'),), QQ, lex)), Symbol('y'))"


def test_DMP():
    assert srepr(DMP([1, 2], ZZ)) == 'DMP([1, 2], ZZ)'
    assert srepr(ZZ.old_poly_ring(x)([1, 2])) == \
        "DMP([1, 2], ZZ, ring=GlobalPolynomialRing(ZZ, Symbol('x')))"


def test_FiniteExtension():
    assert srepr(FiniteExtension(Poly(x**2 + 1, x))) == \
        "FiniteExtension(Poly(x**2 + 1, x, domain='ZZ'))"


def test_ExtensionElement():
    A = FiniteExtension(Poly(x**2 + 1, x))
    assert srepr(A.generator) == \
        "ExtElem(DMP([1, 0], ZZ, ring=GlobalPolynomialRing(ZZ, Symbol('x'))), FiniteExtension(Poly(x**2 + 1, x, domain='ZZ')))"


def test_BooleanAtom():
    assert srepr(true) == "true"
    assert srepr(false) == "false"


def test_Integers():
    sT(S.Integers, "Integers")


def test_Naturals():
    sT(S.Naturals, "Naturals")


def test_Naturals0():
    sT(S.Naturals0, "Naturals0")


def test_Reals():
    sT(S.Reals, "Reals")


def test_matrix_expressions():
    n = symbols('n', integer=True)
    A = MatrixSymbol("A", n, n)
    B = MatrixSymbol("B", n, n)
    sT(A, "MatrixSymbol(Str('A'), Symbol('n', integer=True), Symbol('n', integer=True))")
    sT(A*B, "MatMul(MatrixSymbol(Str('A'), Symbol('n', integer=True), Symbol('n', integer=True)), MatrixSymbol(Str('B'), Symbol('n', integer=True), Symbol('n', integer=True)))")
    sT(A + B, "MatAdd(MatrixSymbol(Str('A'), Symbol('n', integer=True), Symbol('n', integer=True)), MatrixSymbol(Str('B'), Symbol('n', integer=True), Symbol('n', integer=True)))")


def test_Cycle():
    # FIXME: sT fails because Cycle is not immutable and calling srepr(Cycle(1, 2))
    # adds keys to the Cycle dict (GH-17661)
    #import_stmt = "from sympy.combinatorics import Cycle"
    #sT(Cycle(1, 2), "Cycle(1, 2)", import_stmt)
    assert srepr(Cycle(1, 2)) == "Cycle(1, 2)"


def test_Permutation():
    import_stmt = "from sympy.combinatorics import Permutation"
    sT(Permutation(1, 2), "Permutation(1, 2)", import_stmt)

def test_dict():
    from sympy import srepr
    from sympy.abc import x, y, z
    d = {}
    assert srepr(d) == "{}"
    d = {x: y}
    assert srepr(d) == "{Symbol('x'): Symbol('y')}"
    d = {x: y, y: z}
    assert srepr(d) in (
        "{Symbol('x'): Symbol('y'), Symbol('y'): Symbol('z')}",
        "{Symbol('y'): Symbol('z'), Symbol('x'): Symbol('y')}",
    )
    d = {x: {y: z}}
    assert srepr(d) == "{Symbol('x'): {Symbol('y'): Symbol('z')}}"

def test_set():
    from sympy import srepr
    from sympy.abc import x, y
    s = set()
    assert srepr(s) == "set()"
    s = {x, y}
    assert srepr(s) in ("{Symbol('x'), Symbol('y')}", "{Symbol('y'), Symbol('x')}")

def test_Predicate():
    sT(Q.even, "Q.even")

def test_AppliedPredicate():
    sT(Q.even(Symbol('z')), "AppliedPredicate(Q.even, Symbol('z'))")
